A vacuum supply gas cylinder includes a cylinder body, a cylinder valve, a pipeline structure, a first check valve, a positive pressure regulating valve and a second check valve. The cylinder body includes an accommodating space and an opening. The cylinder valve closes the opening. The pipeline structure includes a first and second pipeline. The first check valve is one-way and disposed at the first pipeline. The first check valve has an opening pressure for a gas flow direction from the second end to the first end. The positive pressure regulating valve is disposed at the first pipeline and has an output pressure having a direction same as the gas flow direction from the second end to the first end. The second check valve is one-way and disposed at the first pipeline and is in the same direction as the flow direction of the input and stored gas.

Disclosed is a valve assembly and process for dispensing gas from a storage vessel that comprises a nozzle for discharging the gas. The valve assembly has a passage having a first end is in communication with the nozzle, and a second end in communication with an interior of the storage vessel where the gas is stored. A shut off valve is interposed in the passage for blocking or allowing gas to pass between said first end and the second end of the passage. A check valve may be secured in a bore of the nozzle to prevent accidental gas discharge.

The invention relates to a tank device (1) for storing a gaseous medium, in particular hydrogen, comprising a valve device (2), and a tank (10) and having a longitudinal axis (11). The valve device (2) has a valve housing (20), which is equipped with a pilot valve element (18) that can be moved along the longitudinal axis (11), said pilot valve element (18) interacting with a first valve seat (27) in order to open and close a first outlet opening (56) and thus forming a pilot valve (44). The valve device (2) can be actuated by means of a solenoid coil (14), wherein a main valve element (19) is arranged in the valve housing (20), said main valve element (19) interacting with a second valve seat (40) in order to open and close a second outlet opening (31) and thus forming a main valve (191). The tank device (1) comprises a screw-in housing element (24), wherein the valve device (2) is integrated into a neck region (6) of the tank (10) in a fixed manner by means of the screw-in housing element (24). The valve device (2) is arranged in the tank (10) by means of a tank pressure and is in a closed position by means of a spring (26) when the solenoid coil (14) is deactivated.

A fluid supply package is described, which includes a fluid storage and dispensing vessel, and a fluid dispensing assembly coupled to the vessel and configured to enable discharge of fluid from the vessel under dispensing conditions, wherein the fluid supply package includes an informational augmentation device thereon, e.g., at least one of a quick read (QR) code and an RFID tag, for informational augmentation of the package. Process systems are described including process tools and one or more fluid supply packages of the foregoing type, wherein the process tool is configured for communicative interaction with the fluid supply package(s). Various communicative arrangements are described, which are usefully employed to enhance the efficiency and operation of process systems in which fluid supply packages of the foregoing type are employed.

Methods and apparatus for cryogenic fuel bayonet transfers are disclosed. A disclosed example fuel transfer system includes a fuel tank. The example fuel transfer system also includes a bayonet receptacle extending into an internal volume of the fuel tank, where the bayonet receptacle is to receive a fuel transfer bayonet to fill the fuel tank with fuel and a fuel discharge bayonet to discharge the fuel.

The present disclosure provides a thermal-activated pressure relief device of a fuel cell vehicle, the thermal-activated pressure relief device including: a hollow body mounted at an outlet of a hydrogen tank; a hydrogen discharge block having a plurality of first hydrogen discharge holes and mounted and fixed in an upper portion of the hollow body; a hydrogen discharge pipe having a plurality of second hydrogen discharge holes and connected to a bottom of the hydrogen discharge block; a piston fitted on an outer side of the hydrogen discharge pipe to be able to move up and down and to open and close the second hydrogen discharge holes; a stopper mounted in a lower portion of the hollow body and limiting a downward movement distance of the piston; and a melting alloy disposed between the piston and the stopper and melting at a predetermined temperature or more.

A gas supply vessel for storing and dispensing a reagent gas including a filter such that the vessel is capable of delivering the reagent gas, after it is filtered, at a high level of purity. The filter includes a porous sintered body and is effective to provide a desired level of purity of a supplied reagent gas by flowing the reagent gas through the filter during delivery from the vessel at a low pressure, at a relatively low flow rate, and with a relatively low pressure drop across the filter.

A device, system and method to support the ends of composite pressurized storage vessel, including supporting two ends of a cylindrical composite pressurized storage vessel with an axial rod/tube fixed axially inside the storage vessel fixed at each end; and providing a fluid pathway into the vessel from at least one of the two ends which is not obstructed by the axial rod/tubing.

A retention assembly for a valve assembly of a charged cylinder may comprise a first fitting coupled to the valve assembly and a second fitting coupled to the charged cylinder. A retaining member may be coupled between the first fitting and the second fitting. The retaining member may be disposed within an interior chamber of the charged cylinder.

A screw compressor includes a hollow casing inside which a reservoir for air and oil is realized and on which, in an upper position, a suction group for air from outside the reservoir having at least an air intake valve and at least an air filter; on one lateral end a flow block provided with an oil/air separation device and an oil filter and at least a valve for extracting compressed air are disposed. The casing is provided with an opening on the opposite side with respect to that on which the flow block is provided.

The compressor includes a casing closure flange to which a screw compression unit is fixed that when the flange is placed to close the opening causes the insertion into the reservoir of the unit.